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LEIR model A plan for understanding/upgrading the LEIR performance limitations M.Bodendorfer BE/ABP & LEIR team. LEIR performance, 2013 and LIU Ions Why upgrade? All HI LHC experiments want by 2035: 10nb -1. From: Performance of the injectors with ions after LS1 - PowerPoint PPT Presentation
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LIU Day 2014 – M.Bodendorfer - LEIR model
LIU Day 2014 – M.Bodendorfer - LEIR model
LEIR modelA plan for understanding/upgrading
the LEIR performance limitationsM.Bodendorfer BE/ABP & LEIR team
LIU Day 2014 – M.Bodendorfer - LEIR model 3
LEIR performance, 2013 and LIU IonsWhy upgrade?All HI LHC experiments want by 2035: 10nb-1
Parameter Unit LEIR2013 run
LEIR Baseline upgrade
LEIR Full
upgradePb charge state [-] 54+Output Energy [GeV/u] 0.0722In/Out Bρ [Tm] 1.138 / 4.8Inject. to next machine [-] 1Bunches/ring [-] 2Charge at flat bottom Charges ~6.0x1010 6.0x1010 1.1x1011
Total extracted charge Charges ~5.4x1010 5.4x1010 8.6x1010
From: PERFORMANCE OF THE INJECTORS WITH IONS AFTER LS1D. Manglunki for the LIU-Ions team, CERN, Geneva, Switzerland, 2013
LIU Day 2014 – M.Bodendorfer - LEIR model 4
LEIR NOMINAL cycle
6 in
jecti
ons.
First
at 2
15m
s, th
en
spac
ed 2
00m
s. 20
0μs l
ong.
Extraction@ 2880ms
capture in H2, H4 @ 1780ms
Up to 50% beam loss
(Coasting beam)
B-field
Start ofBeam loss
BHN
cur
rent
[100
A]
LIU Day 2014 – M.Bodendorfer - LEIR model 5
Finding a solution for LEIR
• What we have found so far:1. Working point on 4th order resonance2. Transverse instability at RF capture3. Positive chromaticity in the vertical plane4. Beam loss associated to RF-capture rather than
magnetic Ramp
• Proposed MDs series dedicated to each of the above findings in 2014, 2015.
LIU Day 2014 – M.Bodendorfer - LEIR model 6
1. LEIR working point Design tune: QH=1.82, QV=2.72
Qx - Qy = -1 2Qx - Qy = 1 4Qy = 11 Qx + 3Qy = 10 3Qy = 8 2Qx + 2Qy = 9
LIU Day 2014 – M.Bodendorfer - LEIR model 7
Before: -20msAfter: +20ms
Beam loss continues1815ms
Beam loss starts here
2. LEIR Instability at RF capture and rampPickups output:
LIU Day 2014 – M.Bodendorfer - LEIR model
✗
Bad fit
Bad fit
RF capture
RF capture
Displayed
Displayed
✗Coasting beam & Ecooling
Coasting beam & Ecooling
Beam
loss
Beam
loss
3. Tune and chromaticity measurement after RF-capture
LIU Day 2014 – M.Bodendorfer - LEIR model
Good fitRF capture
RF capture
Displayed✓
Displayed
Good fit(LSQR quadratic)
✓
Beam
loss
Beam
loss
3. Tune and chromaticity measurement after RF-capture
Coasting beam & Ecooling
Coasting beam & Ecooling
LIU Day 2014 – M.Bodendorfer - LEIR model 10
3. Horizontal chromaticity < 0 (after RF capt.)(Horizontal design chromaticy = -1)
Good fit
Fit slop(Linear chromaticity)
Residual of fit
Intensity
LIU Day 2014 – M.Bodendorfer - LEIR model 11
3. Vertical chromaticity > 0 (after RF capt.)(Vertical design chromaticy = -1)
Good fit
Fit slope(Linear chromaticity)
Residual of fits
Intensity
LIU Day 2014 – M.Bodendorfer - LEIR model 12
4. Disentangling beam loss from magnetic ramp
Start mag. ramp
Beam loss with advanced RF-capture
Beam dump
Start ofBeam loss
Advanced by 300ms
BHN
cur
rent
[100
A] RF beam bunching
Higher peak density increases
space-charge
Individual particle tune shift
Individual particles
cross resonance
Loss
LIU Day 2014 – M.Bodendorfer - LEIR model 13
Clues from measurements:1. Working point on 4th order resonance2. Transverse instability at RF capture3. Positive chromaticity in the vertical plane4. Beam loss associated to RF-capture rather than mag. ramp
Summary of observationsBH
N c
urre
nt [1
00A]
4.2.
3.
1.
LIU Day 2014 – M.Bodendorfer - LEIR model 14
Measurement clue and suggested MD:1. Working point on 4th order resonance
1. Explore other regions of the tune space (Qy > 2.75)2. Investigate chromaticity for new tune regions
MD suggestions
LIU Day 2014 – M.Bodendorfer - LEIR model 15
Measuremene clue and suggested MD:1. Working point on 4th order resonance2. Transverse instability at RF capture
1. Study effect of the transverse damper2. Investigate origin of instability with transv. damper off
MD suggestions
LIU Day 2014 – M.Bodendorfer - LEIR model 16
Measuremene clue and suggested MD:1. Working point on 4th order resonance2. Transverse instability at RF capture3. Positive chromaticity in the vertical plane
1. Chrom. < 0 for both planes2. Qmeter software from PS
MD suggestions
LIU Day 2014 – M.Bodendorfer - LEIR model 17
Measuremene clue and suggested MD:1. Working point on 4th order resonance2. Transverse instability at RF capture3. Positive chromaticity in the vertical plane4. Beam loss associated to RF-capture rather than
magnetic ramp1. Try RF-capture with different beam parameters
(bunch length and transverse emittances) to check the impact of space-charge.
2. Study the effect of electroncooling and acceleration.
MD suggestions
LIU Day 2014 – M.Bodendorfer - LEIR model 18
Conclusion & Summary
Further reading:• Plans for the upgrade of CERN’s Heavy Ion Complex, D. Manglunki et al., CERN-ACC-Note-2013-034• LINAC3 tank2 phase change and LEIR performance, M. Bodendorfer, R. Scrivens, CERN-ATS-Note-2013-035• Chromaticity in LEIR performance, M. Bodendorfer & LEIR team, CERN-ACC-Note-2013-0032• Longitudinal emittance reduction in LEIR of ion beams for LHC, M. E. Angoletta, M. Bodendorfer, A. Findlay. S.
Hancock, D. Manglunki, upcoming
So far we have:• found working point on/close to resonance• found transverse instability• found wrong chromaticity• Pb54+ beam loss associated to RF-capture rather than
the magnetic rampThe Plan:• Dedicated MD series for each finding.• Further disentangling of space-charge, transverse
instability and resonant beam loss.• Refine the optics model of LEIR.
LIU Day 2014 – M.Bodendorfer - LEIR model
THANK YOU FOR YOUR ATTENTION!
